Watercraft automation and aquatic effort data utilization

ABSTRACT

A trolling device for a boat includes a trolling motor and a control mechanism. The control mechanism controls at least one of the speed and the direction of the trolling motor. The control mechanism is configured to receive control instructions from an electronic GPS mapping computer to cause the trolling motor to maintain a controlled drift of the fishing boat with respect to an anchor point, water current rate, water current direction, wind, and/or wave action.

BACKGROUND

Fishing efforts and aquatic life preservation efforts include a widerange of dynamic variables which may render such efforts difficult andtaxing in many situations. Watercraft anchoring on an aquatic body isproblematic in many scenarios. Watercraft anchoring is typically astatic manual event that hinders dynamic and automated control of theboat. Historical aquatic data in many situations is non-existent. Anytype of recording of historical aquatic data is typically manual andlabor intensive. Current aquatic data suffers from many of the samefrustrations as historical aquatic data. Furthermore, any type ofsuccess during an aquatic effort is usually the result of the experienceof the angler or scientist and/or trial and error.

SUMMARY

This Summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key and/oressential features of the claimed subject matter. Also, this Summary isnot intended to limit the scope of the claimed subject matter.

Aspects of the disclosure pertain to watercraft automation and aquaticdata utilization for aquatic efforts. In one aspect, an anchor point itsobtained and a watercraft position maintenance routine is actuated tocontrol the watercraft to maintain association with the anchor point. Inanother aspect prior aquatic effort data is obtained in association withan anchor point. In yet another aspect, current aquatic effort data, isgenerated in association with an anchor point. In still another aspect,current aquatic effect data and prior aquatic effort data are utilizedfor prediction generation. In yet another aspect, current aquatic ofeffort data and prior aquatic effort data are utilized to obtain anotheranchor point for a watercraft.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting and non-exhaustive features are described with reference tothe following figures, wherein like reference numerals refer to likeparts throughout the various views unless otherwise specified.

FIG. 1 represents exemplary network overviews for watercraft anchoringand automation.

FIG. 2 represents one example system overview for watercraft anchoringand automation.

FIG. 3 represents one example system overview for watercraft anchoringand automation.

FIG. 4 represents one example interface for watercraft anchoring andautomation.

FIG. 5 represents one example of tours for watercraft anchoring andautomation.

FIG. 6 represents one exemplary operational flow diagram for obtainingand maintaining an anchor position.

FIG. 7 represents one exemplary operational flow diagram for obtainingcurrent aquatic effort data.

FIG. 8 represents one exemplary operational flow diagram for obtainingprior aquatic effort data.

FIG. 9 represents one exemplary operation flow diagram for predictiongeneration.

FIG. 10 represents an exemplary computing device.

DETAILED DESCRIPTION

Embodiments are described more fully below with reference to theaccompanying drawings, which form a part hereof, and which show specificexemplary embodiments. However, embodiments may be implemented in manydifferent forms and should not be construed as limited to theembodiments set forth herein; rather, these embodiments are provided sothat this disclosure will be thorough and complete, and will fullyconvey the scope. Embodiments may be practiced as methods, systems ordevices. Accordingly, embodiments may take the form of an entirelyhardware implementation, an entirely software implementation or animplementation combining software and hardware aspects. The followingdetailed description is, therefore, not to be taken in a limiting sense.

The logical operations of the various embodiments are implemented (1) asa sequence of computer implemented steps running on a computing systemand/or (2) as interconnected machine modules within the computingsystem. The implementation is a matter of choice dependent on theperformance requirements of the computing system implementing thedisclosure. Accordingly, the logical operations making up theembodiments described herein are referred to alternatively asoperations, steps or modules.

Aspects of the disclosure pertain to watercraft automation and aquaticeffort data utilization. As the disclosure below makes clear, an anchorpoint is obtained and a watercraft ion maintenance routine is actuatedto propel the watercraft to maintain association with the anchor point.As one example, an angler may mark a fishing spot with a globalpositioning service (GPS) coordinate and/or the like. Perhaps thefishing spot is next to a dock. When the angler returns to the anchorpoint, the angler may engage a trolling device. The angler may actuate aposition maintenance routine for the GPS coordinate that is next to thedock. In doing so, the troller may automatically propel the watercrafttoward the GPS coordinate. The troller maintains the watercraft at, orwithin a tolerance of, the GPS location. As another example, the anglermay utilize aquatic tours that are locally stored, remotely stored ordynamically updated to the computing device associated with thewatercraft. In this manner, the angler may utilize an aquatic tour tohave the watercraft automatically navigate and maintain anchor points onthe aquatic tour. In other aspects, angler may allow a controlled driftfrom an anchor point. For example, a river current may be flowing atseven miles an hour. The angler may only want drift at two miles anhour. Accordingly, the position maintenance routine may be utilized tooffset the river current by five miles an hour so that the watercraftdrifts from the anchor point at two miles an hour.

Anchoring a watercraft with a ng device provides many unforeseeableadvantages in the angling and scientific world. Weighted anchors may beeliminated from watercraft. Watercrafts are effortlessly anchored to apoint and weighted anchors are not intruded into the aquaticenvironment. Watercraft drift is controlled. Watercraft maneuvering isalso improved. For example, an angler may set an anchor point at a dock.When actuated, the trolling device may pull up next to a dock so anangler may exit the watercraft. Anchoring with a trolling device is adynamic event and anchor points may easily be changed. In the situationwhere two trolling devices are implemented on the watercraft, the anglermay easily spin the watercraft by switching the anchor points of thetrolling devices. Also, in the situation where two trolling devices areimplemented, the angler may maintain a rear portion of the watercraftwith respect to the front portion of the watercraft so that the ends ofthe watercraft do not drift with respect to one another. Otheradvantages include providing a “data container” associated with theanchor point. For example, the GPS location may also be an identifier toassociate data such as current aquatic effort data, prior aquatic effortdata, services, etc. The “data container” may also facilitate predictivegeneration. Still other advantages provide aquatic tour associationautomate anchor points and aquatic body navigation.

As the disclosure below also makes clear, current aquatic effort datamay be associated with a “data container” of the anchor point. As oneexample, an angler may set an anchor point near a dock. The datacontainer associated with the anchor point may automatically populatewith such data as the temperature of the water, weather conditions,equipment types, caught aquatic life, duration at the anchor point, etc.This data may be locally stored, remotely stored and/or dynamicallystored as the data is generated. The data may remain private made publicfor other anglers.

Collecting current aquatic effort data in such a manner provides manyunforeseeable advantages in the angling and scientific world. Data maybe easily and efficiently collected and associated with an anchor pointon an aquatic body. Trends may be realized. Data may be easily madeaccessible for other anglers. An angler may easily collect that relevantdata and associate the data with the duration of the positionmaintenance routine that is anchoring the watercraft to a position onthe aquatic body. In this manner, angling time may be compared to aquantity of aquatic life caught. The current aquatic effort data mayalso be utilized to update a position maintenance routine.

As the disclosure below also makes clear, prior aquatic effort data maybe obtained from a “data container” of the anchor point. For example, anangler may return to a prior angling spot and easily access the angler'sprior history at the angling spot by using an anchor point identifier toautomatically obtain prior aquatic effort data associated with theanchor point identifier. The angler can access prior equipment used,water conditions, success at the angling spot, duration of the positionmaintenance routine at the angling spot etc. In the situation where theangler has never been to the fishing spot before, the angler may accessprior aquatic effort data on a network or data that has been uploaded toa computing device associated with the watercraft. Therefore, the anglermay realize angling tactics that have worked for other anglers in thepast. The prior aquatic effort data may include blog information andguide information. As an example, a blog from a prior angler may tellthe current angler to “cast near the dock.” The prior angler may haveassociated a quantity of aquatic life caught near the dock.

Obtaining prior aquatic effort data in such a manner provides manyunforeseeable advantages in the angling and scientific world. Trends maybe easily identified. Tours may be automated and networked. A watercraftmay be and effortlessly controlled to account for the prior aquaticeffort data and/or to account for the prior aquatic of data in light ofthe current aquatic effort data. During slow times, the angler may beentertained with blog data. Relevant internet services may be obtainedthat are associated with past trends. The prior aquatic effort data mayalso be updated with the anglers current aquatic effort data todynamically and automatically keep the prior aquatic effort data up todate. Aquatic tour services may easily set up automated tours foranglers. For example, an aquatic tour service may review the prioraquatic effort data and generate a tour that has been successful in thepast. The tour may then be made public so that current anglers canautomate a position maintenance routine to take the tour.

As the disclosure below further makes clear, predictive suggestions maybe generated in association with the anchor point. The current aquaticeffort data may be compared to the prior aquatic effort data to generatea predictive suggestion. For example, current temperature, currentlocation, current time, current date, current water condition, and/orcurrent weather conditions may be compared to prior temperature, priorlocation, prior time, current date, prior water condition, and/or priorweather conditions. This comparison may indicate similarities in theconditions. The similarities may be used to generate a predictivesuggestion regarding, for example, a tour to utilize, a position tomaintain, a bait to use, a lure to use, a rod to use, a reel to use,etc. The prediction suggestions may change as the current aquatic effortdata is obtained to indicate matches to other prior aquatic effort dataServices associated with an aquatic effort may also be updated. Forexample, perhaps a time of day indicates that the angling hours in theday are almost over. The service may automatically make dinnerreservation at a local eatery.

Predictive generation provides many unforeseeable advantages in theangling and scientific world. Trends may be easily identified. Anglingsuggestions are easily obtained. Tours may be dynamically updated ascurrent aquatic effort data changes. Position maintenance routines maybe dynamically updated and services may be dynamically updated accordingto current aquatic effort data.

In the manner provided herein, aquatic efforts, data collection, aquaticservices and watercraft positioning may be automated. Several examplesare provided herein below. These examples are not meant for limiting themyriad of possibilities associated with position maintenance, currentaquatic effort date, prior aquatic effort data, and predictivegeneration. These examples are meant to give a few examples of thepossible unforeseeable benefits of the features more set forth herein.

FIG. 1 represents exemplary network overviews for watercraft anchoringand automation. Network overview 100 may include interne 102 and one ormore watercrafts 104, 106 and 108. Watercrafts 104, 106 and 108 aredepicted herein for exemplary purposes only. In one aspect, watercrafts104, 106 and 108 are personal fishing watercrafts and are distinguishedfront commercial fishing vessels. Watercrafts 104, 106 and 108 mayinclude any combination of network connectivity, number of trollingdevices, anchor points, and anchor point tolerances. For example, awatercraft may be connected to the internet via wireless connectivity.Two watercraft may be networked together to exchange information via theinternet, a radio frequency, and or an infrared frequency. A watercraftmay have no network connectivity, where features of the disclosure arelocally facilitated. In other aspects, a watercraft may use anotherwatercraft to network to the internet or another watercraft in a meshnetwork manner. These and any of the other myriad of networkpossibilities may be included to facilitate watercraft automation andaquatic effort data utilization.

Watercraft 104 includes a connection to interact 102 for uploading anddownloading data. Watercraft 104 may also be networked to watercraft 106for direct communication. Watercraft 104 also includes a single tollingdevice 110 located at the front of watercraft 104. Trolling device 110may include a trolling motor with an automated speed and directionalcontrol mechanism for controlling the trolling device via a remote.Remote control trolling devices and the mechanics associated with remotecontrol trolling devices are generally known in the angling industry. Inaspects of the disclosure, trolling device 110 is in communication witha computing device such as the computing device illustrated in FIG. 10for receiving direction and propelling inputs. Trolling device 110 maybe associated with anchor point 112. Anchor point 112 may include ananchor point associated with a GPS device, a relative positioningdevice, a depth finder device, a sonar device, a gyroscope device, amagnetic compass, etc. Stated another way, anchor point 112 may beassociated with any type of device that is functional to identify aposition on an aquatic body and determine when the current position ofwatercraft 104 has moved from the identified position. Anchor point 112may also have art associated tolerance 114. Tolerance 114 may indicate adistance from anchor point 112 that watercraft 104 may drift before aposition maintenance routine is actuated. Tolerance 114 may include “no”tolerance, meaning that the current position is maintained at anchorpoint 112 and deviation from the anchor point 112 will actuate theposition maintenance routine. Tolerance 114 may also be a drifttolerance. Stated another way, tolerance 114 may allow drift from anchorpoint 112 at a rate. In operation, a computing device associated withwatercraft 104 downloads and uploads data from intern& 102 and/orwatercraft 106. Anchor point 112 is set and trolling device 110 iscontrolled to maintain trolling device 110 within tolerance 114. Inaspects associated with watercraft 104, the rear portion of watercraft104 may drift relative to the front portion of watercraft 104.

Watercraft 105 is similar to watercraft 104, but watercraft 106 includestwo trolling devices and two anchor points are set with two tolerances.Watercraft 106 may be networked with the internet, watercraft 104, andwatercraft 108. In operation, a computing device associated withwatercraft 105 downloads and uploads data from internet 102 and/orwatercraft 104 and/or watercraft 108. Anchor points 112 are set andtrolling devices 110 are controlled to maintain trolling devices 110within tolerances 114. In aspects associated with watercraft 106, therear portion of watercraft 105 and a front portion of watercraft 105 maybe maintained or moved relative to one another. Accordingly, watercraft106 may be automatically controlled to switch anchor points 112 andcause watercraft 106 to spin. Watercraft 106 may also move sideways.Also, the rear portion of watercraft 106 may be maintained relative tothe front portion of watercraft 106 so that no portion of watercraft 100drifts from wind or wave action. In other aspects, watercraft 106 may becontrolled to drift at a controlled rate relative to a current and/orcurrent direction.

Watercraft 108 is similar to watercraft 104, but watercraft 108 includestrolling device 110 located in the center portion of watercraft 108.Also, watercraft 108 is not directly connected to internet 102. In oneaspect, watercraft 108 may include a direct network connection towatercraft 106. In such a situation, watercraft 108 may communicate withwatercraft 106, and watercraft 108 may use watercraft 106 as a networknode to communicate with watercraft 104 and/or internet 102. In aspectsassociated with watercraft 108, position maintenance data associatedwith the control of watercraft 108 may be stored locally and notpublicly shared. In other aspects, data is maintained on a local storagedevice such as a CD-ROM, a hard drive or an external storage device.Data may be uploaded, downloaded, and/or synchronized before and afteran aquatic effort if desired. Even though three watercraft scenarios aredepicted in FIG. 1, any combination may exist. Watercrafts may includeany level of connectivity to a network, any number of trolling devices,and any location of trolling devices. As another example, the networkmay include a closed network between a few anglers and/or a network thatincludes a password protected group of anglers. Even though not depictedin FIG. 1, certain aspects of the disclosure are relevant to anchor awatercraft with a weighted anchor. These features are furtherhighlighted herein.

FIG. 2 represents one example system overview for watercraft anchoringand automation. System overview 200 represents a modular overview ofsome features of the disclosure. System overview 200 may be integratedas a combination of software and hardware elements, an operating systemor any combination thereof. Hardware, databases, software orapplications referenced herein may be integrated as a single feature orinclude various features in communication with one another. Softwareand/or hardware elements are depicted herein for explanatory purposesonly and not for limiting the configuration to multiple elements or asingle element performing several functions. For example, in FIG. 2,watercraft automation component 202 may include a position module 204,interface module 206 and sensors 208. Reference numbers 202-208 mayinclude separate programs, separate databases and separate hardware.Reference numbers 202-208 may also include a single program or anycombination of single and multiple programs.

Watercraft automation component 202 and associated components 204-208may include computing device 1000 as exemplified in FIG. 10. Watercraftautomation component 202 may include a telephone, cellular telephone,satellite telephone, stationary computing device, mobile computingdevice, televising device, mobile audio device, watch device, or anyother device that may implement watercraft automation as set forthherein. In one aspect, watercraft automation component 202 is depictedto show a physical device with components 204-208 integrated thereon. Inanother aspect, watercraft automation component 202 is depicted to showa communication association between components 204-208.

Watercraft automation component 202 communicates with trolling device210 to facilitate setting anchor point 212 and tolerance 214. Watercraftautomation component 202 may also be in communication with internet 216to communicate position maintenance data, current aquatic effort data,prior aquatic effort data, services, predictive suggestions and/or thelike. In other aspects, the watercraft automation component 202 is incommunication with an open network, a closed network, a passwordprotected network, and/or an internet site having group privileges. Inother aspects, watercraft automation component 202 may communicate witha local storage and local programs. In still other aspects, watercraftautomation component 202 communicates with other watercraft. Watercraftautomation component 202 may also receive data associated with sensor208 and interface module 206. As more fully set forth below, watercraftautomation component 202 determines a proper position maintenanceroutine for trailing device 210, uploads and downloads appropriate datefrom internet 216 (or a local storage), and receives and displaysappropriate data on interface module 206.

Position module 204 may include a GPS device, a relative positioningdevice, a depth finder device, a gyroscope device, a magnetic compassdevice, a sonar device, etc. Stated another way, position module 204 maybe associated with any type of device that is functional to identify aposition on an aquatic body and determine when the current position of awatercraft has moved from the identified position. In other aspects,position module 204 determines a rate of fit from anchor point 212. Inone aspect, position module 204 may identify a current position andcommunicate the current position to watercraft automation component 202to determine whether the current position is within a tolerance ofanchor point 212. In other aspects, position module 204 includesinstructions to determine whether the current position is within atolerance of anchor point 212.

Sensors 208 may include a plurality of different sensor types, of whicha few are described herein. The sensor data may be communicated towatercraft automation component 202 to thereby update a positionmaintenance routine, position module 204, storage, interface module 206,and/or storage associated with internet 216. In one aspect, sensors mayinclude an environmental sensor. Environmental sensors may include aweather sensor, a temperature sensor, a water depth sensor, atemperature sensor, a water sensor, a water flow sensor, a barometricsensor, a wind sensor, a rain gage, a water quality sensor, an airquality sensor, and/or any other type of sensor for determiningenvironmental conditions. Sensor may also include watercraft sensors.Watercraft sensors may include a fuel sensor, oil sensor, batterysensor, a watercraft drift sensor, a GPS sensor, and/or any other typeof sensor for determining conditions of a watercraft. In other aspects,a sensor may be associated with a downrigger. The downrigger sensor mayinclude a depth sensor, water temperature sensor, ph sensor, waterclarity sensor, and for any other sensor type described herein. In thismanner, data associated with a water depth may be obtained. A sensor mayalso include a radio frequency identifier (RFID) sensor. Such sensorsmay be configured to detect RFID tags associated with aquatic life, alure, a reel, a rod and/or any other equipment associated with anaquatic experience. The RFID sensor may be used to quickly andefficiently log and store data. For example, an RFID tag may beassociated with a lure and encoded with data that indicates the lureweight, type, size, shape, category, color, etc. In one aspect, the RFIDtag is imbedded in the head of the lure and balanced to provide propermovement as the lire travels through the water. A sensor may alsoinclude a bar code reader. The bar code reader may detect a bar codeassociated with a lure, a reel, a rod and/or any other equipmentassociated with an aquatic experience. The bar code reader may be usedto quickly and efficiently log and store data. Sensors may also includetrolling sensors. Trolling sensors may detect a direction, a propellingdirection, a propelling speed, and the like. A myriad of other sensorsmay be associated with the watercraft in order to detect currentconditions associated with an aquatic experience.

Interface module 206 may include aspects of computing device 1000illustrated in FIG. 10. Interface module 206 may include a display andinput device. Such input devices may include a touch screen, anelectronic pen, a mouse device, a keyboard, and any other type of inputdevice for inputting and/or displaying data. Interface module 206 isconfigured to receive inputs from a user and communicate data to a user.In other aspects, interface module 206 communicates with sensors 208,position module 204, internet 216, watercraft automation component 202,and/or trolling device 210. For example, interface module 206 maydisplay data associated with FIG. 4. Interface module 206 may alsoreceive input data and associate the input data with watercraftautomation component 202. Watercraft automation may then update storage,interface module 206, a position maintenance routine and/or storageassociated with internet 216.

Watercraft automation component 202 is configured to communicate datawith interne 216. In the situation where watercraft automation component202 is not associated with interne 216, watercraft automation component202 may be configured to communicate with a local storage. In otheraspects, watercraft automation component 202 initially uploads data fromthe internet before an aquatic effort. Data is updated to a localstorage during an aquatic effort and data is updated to internet 216after an aquatic effort. The data may be dynamically and automaticallysynchronized during an aquatic effort in other aspects of thedisclosure. In some aspects, data is locally maintained and not uploadedto internet 216. This may occur when an angler desires keeping anglingsecrets from other anglers.

The data communicated between watercraft automation component 202 andinternet 216 (network, or a local storage if the watercraft automationcomponent 202 is not networked) may include position maintenance data.Position maintenance data may be automatically generated by control ofthe troller and/or position maintenance data may be input by a user. Theposition maintenance data may include anchor point data. The anchorpoint data may include a name of an anchor point, an identifier of ananchor point, directions associated with an anchor point, mapping dataassociated with an anchor point, etc. The position maintenance data mayfurther include an anchor point identifier. The anchor point identifiermay be an identifier for identifying a “container” for storing aquaticeffort data in association with the anchor point. In another aspect, theidentifier may be associated with a new container for data. In stillanother aspect the anchor point may include an anchor point apart fromthe anchor point that is maintaining the position of the watercraft. Inone aspect, the identifier is a GPS coordinate. However, the anchorpoint identifier may also include an identifier associated with a depthfinder, a relative position, a sonar position, a gyroscopic position, amagnetic compass position, an imagery position or any other type ofidentifier that is used for marking a position. Position maintenancedata may further include anchor point duration data. Stated another way,the time, date and duration of maintaining the watercraft in associationwith an anchor point. Such duration data may be relevant in determiningan amount of time an angler is anchored at a position and comparing theduration against a quantity of aquatic life caught. The positionmaintenance data may also include data associated with the tolerance ofthe anchor point. For example, the tolerance may include a distancetolerance, no tolerance, and the like. Other tolerances may include adrift rate tolerance.

The data communicated between watercraft automation component 202 andinterne 216 (network, or a local storage if the watercraft automationcomponent 202 is not networked) may also include prior aquatic effortdata. Prior aquatic effort data includes data that is association with adata container identified by an anchor point identifier. The prioraquatic effort data may include data from prior angling experiences,data from a tour service and/or any other type of data that may havebeen associated with an anchor point identifier prior to a currentangling experience. For example, prior aquatic effort data may includeprior environmental data associated with an anchor point. Prior aquaticeffort data may include position maintenance data associated with aprior tour or with a prior angling experience. Prior aquatic effort datamay include blog and/or graffiti data associated with prior experiencesat the anchor point. Blog and/or graffiti data may include text, videostreams, maps, satellite imagery and/or photographs. Internet servicesmay also be included in the prior aquatic effort data. Such internetservice may include prior services used during a virtual tour or anglingexperience. Internet services may include mapping services, laws,angling rules, angling limits, restaurants and hotels within proximity,emergency services, water discharge data, weather report data, damreports, moon phase reports, tide predictions and/or the like. In otheraspects, prior aquatic effort data may include river data, waterelevation data, data from a government agency, water discharge data,etc. Prior aquatic effort data may further include prior caught aquaticlife type data and prior aquatic quantity data. For example, a fish typeand a quantity of fish from a prior experience may be obtained inassociation with an anchor point identifier. Similarly, prior aquaticeffort data may include a bait type, a lure type, a rod type, a redtype, and the like. The data may be from a prior experience and may beobtained in association with an anchor point.

The data communicated between watercraft automation component 202 andinternet 216 (or a local storage if the watercraft automation component202 is not networked) may also include current aquatic effort data.Current aquatic effort data may include automatically generated data(e.g. data from sensors or the control of the watercraft) and/or thedata may include user input data. The current aquatic effort data may beassociated with the data container identified by the anchor pointidentifier. Current aquatic effort data may include data collected fromsensors. Current aquatic effort data may also include data collectedfrom a position maintenance routine. Position maintenance data mayinclude the duration of maintaining an anchor point. The positionmaintenance data may also include data associated with the directionalcontrol of the troller (e.g. compass directions, relative direction,etc). Current aquatic effort data may include RFID data. For example, anRFID sensor may detect an RFID tag that is associated with a lure, rod,reel, and/or aquatic life. The RFID tag may be encoded with informationthat indicates a type, date, etc. Similarly, the current aquatic effortdata may include barcode reader data. For example, a barcode reader maydetect a bar code that is associated with a lure, rod, reel, and thelike. The bar code may be encoded with information that indicates atype, date, etc. In other aspects, current aquatic data may include atype and number of aquatic life caught. Such data may be manuallyentered into a user interface and/or detected by an RFID tag associatedwith the aquatic life. In other aspects, a scale sensor is associatedwith watercraft automation component 202 and the weight of the aquaticlife is automatically associated with watercraft automation component202 upon associating the aquatic life with the scale sensor.

Current aquatic effort data may further include data that is associatedwith a virtual tour. For example, as an angler navigates a virtual tour,data may be obtained. Data may include duration of the tour, success onthe tour, comments associated with the tour, and/or other informationthat describes the angling tour. Current aquatic effort data may furtherinclude blog data and graffiti data (e.g. text data, video data, and/orpicture data). Blog data and graffiti data may be comments entered by anangler regarding a particular angling location. The comments may beassociated with an angler's blog and/or posted as graffiti inassociation with the data container of the anchor point identifier. Thecurrent aquatic effort data may further include internet services. Forexample, interact services may be communicated that provide servicesassociated with the anchor point identifier. Such services may includemapping services, laws, angling rules, angling limits, restaurants andhotels within proximity, emergency services, dam reports, waterdischarge reports, government agency reports, moon phase reports, tidepredictions, weather reports, lake reports, ocean reports and/or thelike.

Current aquatic effort data may further include aquatic life type dataand aquatic quantity data. For example, a fish type and a quantity offish may be input or detected for association with an anchor pointidentifier. Similarly, current aquatic effort data may include a baittype, a lure type, a rod type, a reel type, and the like. The data maybe input by a user and/or detected via a sensor.

The data communicated between watercraft automation component 202 andinternet 216 (or a local storage if the watercraft automation component202 is not networked) may further include predictive suggestions.Predictive suggestions are generated by comparing the current aquaticeffort data associated with an anchor point to prior aquatic effort dataassociation with an anchor point. In other aspects where prior aquaticeffort data is not associated with an anchor point, the current aquaticeffort data may be use to make generalized or default predictivesuggestions in regard to the anchor point. As an example, currentaquatic effort data may indicate that no fish have been caught with lureX for the last twenty minutes. Past aquatic effort data for prior toursmay indicate that when lure X does not work, lure Y has worked in thepast in association with an anchor point. Accordingly, the interfacewill populate with a suggestion to switch to lure Y. In such a manner,predictive suggestions may include position maintenance data. Theposition maintenance data may be generated from a comparison of currentaquatic effort data to prior aquatic effort data and indicate a positionto maintain that has been successful in the past under the currentconditions. In such situations, watercraft may be automaticallynavigated to a new anchor point.

Predictive suggestions data may include virtual tour data. The virtualtour data may suggest a detour from a current tour by comparing thecurrent aquatic effort data to the prior aquatic effort data andindicating a detour that has been successful in the past under thecurrent conditions. Similarly, predictive suggestions data may includebait type data, lure type data, rod type data, and reel type data. Acomparison is made between the current aquatic effort data and the prioraquatic effort data to make a predictive suggestion that has beensuccessful in the past under the current conditions. The comparison mayinclude a range of matching values. As an example, a current watertemperature may be 80 degrees. The predictive suggestion may find thatat 75 degrees a certain lure has been successful in the past.Accordingly, the predictive suggestion data may give an indication toswitch to the certain lure. In a similar manner, ranges may be set forthe date, time of day, sensor data, and the like.

Other predictive suggestions may be associated with services. Forexample, the current aquatic effort data may indicate that ten fish havebeen caught. A service may indicate that ten fish is a limit for thelake. The current fish caught is compared to the limit of the serviceand a predictive generation is created. In this example, the predictivegeneration may include data that states that the angler has reached alimit and whether to confirm dinner reservations at a local restaurant.In other aspects, the watercraft may be controlled via predictivesuggestions. For example, when current aquatic effort data is comparedto prior aquatic effort data, a predictive suggestion may indicate thatanew anchor point should be maintained. In such a situation, watercraftautomation component 202 automatically controls the troller to navigateto a new anchor point.

The disclosure herein includes a few examples of predictive generationand automation from predictive generation. A myriad of possibilitiesexist when current aquatic effort data associated with an anchor pointis compared to prior aquatic effort data of an anchor point. In oneaspect, the anchor point is associated with a weighted anchor. However,in other aspects the anchor point is associated with a positionmaintenance routine of a trolling device. By associating the anchorpoint with a position maintenance routine, the position maintenanceroutine may be dynamically updated to control the trolling device inlight of current aquatic effort data, prior aquatic effort data andpredictive suggestion data.

FIG. 3 represents one example system overview for watercraft anchoringand automation. System overview 300 represents a modular overview ofsome features of the disclosure. System overview 300 is similar tosystem overview 200 except system overview 300 includes two trollingdevices, two position maintenance routines, two anchor points and twotolerance. As such, the front and the rear of the watercraft may be moreprecisely controlled with respect to one another and provide for aricher experience during an aquatic tour. System overview 300 includeswatercraft automation component 302, position module 304, interfacecomponent 306, sensors 308, trolling device 310, anchor point 312,tolerance 314 and internet 316. System overview 300 also includes secondtrolling device 316, second anchor point 318 and second tolerance 320.Elements 316-320 may be implemented in a similar manner as elements310-314.

In one aspect, even though two anchor points are depicted, a singleanchor point identifier (e.g. either anchor point 312 or anchor point318) may be utilized for identifying a container for associating datawith a position. In system overview 300, trolling device 310 may becontrolled relative to trolling device 316. For example, the front ofthe watercraft may be moved relative to the rear of the watercraft. Asanother example, trolling device 310 may be controlled to switch anchorpoints with trolling device 316 to cause the watercraft to rotatedegrees. Such a movement may be useful when an aquatic tour includesboth sides of the watercraft. By rotating the watercraft, an angler maybe easily directed to the position where the tour data indicates tocast. In other aspects, trolling device 310 and trolling device 316 maybe controlled to “shift” the boat sideways. Such a movement is usefulwhen pulling up to a dock, etc. In other aspects, the watercraft may bemaintained perpendicular to a current flow of a river and drift at arate that is more or less than the current of the river.

FIG. 4 represents one example interface for watercraft anchoring andautomation. Interface 400 may include display 402 having one or moregenerated panes. Interface 400 may include position maintenance pane404, prior aquatic effort data pane 406, current aquatic effort datapane 408, and predictive suggestions pane 410. Panes 404-410 may includedata, controls, fields and tools. As an example, interface 400 mayinclude displayed data for use bye an angler. Interface 400 may includecontrols for controlling a trolling device, sensors, internetconnection, position module, etc. Interface 400 may also include fieldsfor entering data associated with the position maintenance routine,prior aquatic effort data, current aquatic effort data and/or predictivesuggestions. Interface 400 may also various tools for managing data andcontrols associated with the features set forth herein. Interface 400includes several sub-panes for exemplifying some of the features ofinterface 400. Position maintenance pane 404 may include data, controls,features and tools associated with anchor point data 412, anchor pointidentifier data 414, anchor point duration data 416 and anchor pointtolerance data 418. Prior aquatic effort data pane 406 may include data,controls, features and tools associated with environmental data 420,position maintenance data 422, virtual tour data 424, blog data 426,graffiti data 428, interact services 430, aquatic life type data 432,aquatic quantity data 434, bait type data 436, lure type data 438, rodtype data 440, and reel type data 442. Current aquatic effort data pane408 may include data controls, features and tools associated with sensordata 444, RFID data 446, environmental data 448, position maintenancedata 450, virtual tour data 452, blog data 454, graffiti data 456,intern& services 458, aquatic life type data 460, aquatic quantity data462, bait type data 464, lure type data 466, rod type data 468 and reeltype data 470. Predictive suggestions pane 410 may include data,suggestions, predictions, controls, features and tools associated withposition maintenance data 472, virtual tour data 474, bait type data476, default predictive suggestions 478, lure type data 480, rod typedata 482, and reel type data 484.

FIG. 5 represents one example of a tour for watercraft anchoring andautomation. Exemplary tour overview 500 includes a lake edge 502, afirst tour 504 and a second tour 506. A tour may include a usergenerated tour, a tour downloaded from the internet, a tour associatedwith a removable computer-readable storage medium, and/or a “live” tourthat is automatically updatable from a network. First tour 504 includesa first leg 508, a second leg 510 and transport leg 512. Second tour 506shows a tour with a possible detour route. First tour 504 and secondtour 506 depict a few tour examples associated with the disclosure. Amyriad of tours are possible in light of the disclosure.

As an example m association with first tour 504, an angler may enter anaquatic body somewhere near anchor point A1 First tour 504 may beassociated with a watercraft automation module. Upon receiving a “starttour” command, a trolling device may detect a current position andcompare the current position to the position of anchor point A1. Thewatercraft automation module controls the trolling device to propel thewatercraft from the current position to anchor point A1. At anchor pointA1, an angler has entered first leg 508. The tour associated with anchorpoint A1 may also include an anchor point duration as with anchor pointA1. Accordingly, a position maintenance routine may maintain thewatercraft at anchor point A1 until the anchor point duration hasexpired. At such expiration, the watercraft is propelled from anchorpoint A1 to anchor point A2. At any time during the tour, the control ofthe watercraft according to the tour may be modified. For example, anangle may override the tour to instigate a forced detour or frolic fromthe tour. In other situations, the current aquatic effort data, prioraquatic effort data and/or prediction suggestion may modify the tourfrom the tour as initially set.

Transport leg 512 is indicated between anchor point A3 and anchor pointA4. When the anchor point duration association with anchor point A3expires, the first to may eater a transport mode. The transport mode maybe actuated when the distance between anchor points is too far for atrolling device to efficiently navigate. An example criteria may includea 1 distance between anchor points actuates a transport mode. When thewatercraft automation module is in a transport mode, a mapping programmay populate the interface to navigate an angler to a distal anchorpoint via a high horse power motor. Stated another way, transport modemay indicate that the watercraft cannot be automatically navigated tothe next anchor point. At anchor point A4, an angler has begun secondleg 510 of first tour 504. The watercraft automation module thenautomatically navigates the watercraft and maintains the watercraft atanchor points A4-A7.

Second tour 506 may depict a tour with a detour or frolic. In anotheraspect, second tour 506 may depict a tour on river. With regard to adetour, the watercraft automation module may control a trolling deviceto navigate a watercraft to anchor point B4. As an example of a detour,at anchor point B4, the water temperature may increase several degreesand a sensor may indicate that the angler is catching more fish at thehigher temperature. The tour may indicate a detour to anchor point B5′as opposed to anchor point B5. A prediction may indicate that anchorpoint B5 is deeper in the lake and therefore the water will be coolerthan the more shallow anchor point B5′. Second tour 506 mayautomatically cause the watercraft automation module to navigate thewatercraft to anchor point B5′. In other aspects, the detour may besuggested and accepted or denied by a user input. As illustrated in theabove example, the tour is dynamically modified according to currentconditions of the tour. The tour may also be modified by comparingcurrent conditions of the tour to past conditions of the tour. As such,the watercraft automation module puts an angler in the best position forsuccess.

As another example, second tour 506 may represent a tour along a river.Anchor points B1-B7 may represent a path associated with the currentflow along a river. When transitioning from anchor point B1-B2, aposition maintenance routine may cause a controlled drift. Many timeswhen angling a river, an angler desires a controlled drift in thedirection of the current. Sometimes the current is too rapid for anglingat the rate of the current. Accordingly, a controlled drift may beinstigated to allow the watercraft to drift at a slower rate than thecurrent of the river. In doing so, a position module may detect acurrent position of a watercraft and a relative speed of the watercraft.The relative speed of the watercraft may be detected through a watercurrent sensor or by detecting the distant change over a time intervalassociated with an anchor point. Once the relative speed of thewatercraft is detected, the trolling device may be controlled by thewatercraft actuation module to reduce or increase a drift. As anexample, the river current speed may be seven miles an hour. In thesituation where the angler desires a two mile an hour drift, thewatercraft is automatically propelled against the current at a rate offive miles an hour. As another example, the speed of the river currentmay be one mile an hour. In the situation where the angler desires a 5mile an hour drift, the watercraft is automatically propelled with thecurrent at a rate of four miles an hour. The same principles may beimplemented for drift associated with the wind or wave action. FIG. 5represents a few examples associated with anchor points, tours, legs,transport legs, detours, frolics and drift. Other combinations of toursexist and FIG. 5 should not be read as limiting but as a few examples.

FIG. 6 represents one exemplary operational flow diagram for setting andmaintaining an anchor position. Operational flow 600 begin s at startoperation 602 and continues to operation 604 where an anchor point isobtained. An anchor point may include an identifier such as adirectional coordinate, a map coordinate a GPS identifier and the like.The anchor point may be obtained by a user selection. For example, auser may select a “set anchor” actuator on a display. In such asituation, a GPS coordinate may be received an the anchor point is setto the GPS coordinate. In other situations, an anchor point may beobtained from an intense service, such as a tour service. An anchorpoint may also be a stored anchor point and obtained from a localstorage or a removable storage device. In yet another example, an anchorpoint may be obtained from another watercraft via a network, theinternet, a radio frequency, infrared frequency or the like.

After the anchor point is obtained, operational flow 600 continues tooperation 606 where a position maintenance routine for the anchor pointis instantiated. The position maintenance routine may be automaticallyinstantiated in association with a tour. In other aspects, a user mayinstantiate a position maintenance routine by selecting an object of theuser interface. The position maintenance routine may maintain thewatercraft within a tolerance of an anchor point. In another aspect, theposition maintenance routine maintains a drift rate away from the anchorpoint.

Operational flow 600 continues to decision operation 608 where it isdetermined whether the current position is within a tolerance of theanchor point. The tolerance may include a rate of change toleranceassociated with drift. In other aspects, the tolerance includes a staticposition tolerance. The tolerance may also include “no” tolerance. Inone aspect, at decision operation 608, the current position of thewatercraft is detected. For example, the current position may bedetected via GPS. If the current position is within the tolerance of theanchor point, operational flow 600 loops back up until the currentposition is not within the tolerance of the anchor point. Operationalflow 600 continues to operation 610 when the current position of thewatercraft is not within the tolerance of the anchor point. In anotheraspect, at decision operation 608, speed of the watercraft relative tothe anchor point is determined. When the speed of the watercraftrelative to the anchor point is within the tolerance of the anchorpoint, operational flow 600 loops back up until the speed of thewatercraft relative to the anchor point is not within the tolerance ofthe anchor point. When the speed of the watercraft relative to theanchor point is not within the tolerance of the anchor point,operational flow 600 continues to operation 610.

At operation 610, the direction to the anchor point is determined. Thedirection may include a compass direction, GPS directions, radialcoordinate directions, rectangular coordinate directions and the like.As an example, the current position may be compared to an anchorposition and it may be determined that the anchor point is in the northeast direction. Continuing to operation 612, the propulsion device isadjusted for the determined direction. The propulsion device may beautomatically rotated so that when the propulsion device is actuated itpropels the watercraft in the determined direction of the anchor point.

At operation 614, propulsion device is automatically actuated to propelthe watercraft in the determined direction. In one aspect, propellingcontinues until the current position of the watercraft is equal to theanchor point. In another aspect, propelling continues until the currentposition of the watercraft is within the tolerance of the anchor point.In yet another aspect, propelling continues to maintain a rate of driftfrom the anchor point.

Operational flow 600 continues to decision operation 616 where it isdecided whether to end the position maintenance routine for the anchorpoint. In one a aspect, position maintenance routine is terminated by auser selection. In another aspect, a position maintenance routine isterminated automatically in association with a tour. In yet anotheraspect, a position maintenance routine is to as dictated oy currentaquatic effort data, prior aquatic effort data, and/or predictionsuggestion data. In still another aspect, a position maintenance routineis terminated by the ending of an anchor point duration. When the end ofthe position maintenance routine for the anchor point is not reached,operational flow 600 continues to decision operation 608 as set forthabove. When the end of the position maintenance routine is reached,operational flow 600 continues to decision operation 618 where it isdetermined whether to obtain another anchor point. When it is determinedto obtain another anchor point, operational flow 600 continues todecision operation 606. When it is determined not to obtain anotheranchor point, operational flow continues to end operation 620.

FIG. 7 represents one exemplary operational flow diagram for obtainingcurrent aquatic effort data. Operational now 700 begins at startoperation 702 and continues to operation 704. At operation 704, ananchor point is obtained. An anchor point may include an identifier suchas a directional coordinate, a map coordinate a GPS identifier and thelike. The anchor point may be obtained by a user selection. For example,a user may select a “set anchor” actuator on a display. In such asituation, a GPS coordinate may be received and the anchor point is setto the GPS coordinate. In other situations, an anchor point may beobtained from an internet service, such as a tour service. An anchorpoint may also be a stored anchor point and obtained from a localstorage or a removable storage device. In yet another example, an anchorpoint may be obtained from another watercraft via a network, theinternet, a radio frequency, infrared frequency or the like.

Operational flow 700 continues to operation 706 where aquatic servicesare obtained. Aquatic services may be associated with an internetserver, locally stored on a computing device and/or associated with aremovable computer-readable storage medium. To obtain the services, theidentifier associated with the obtained anchor point is matched toaquatic services. For example, services may be identified by a GPScoordinate. When the GPS identifier of the anchor point matches the GPScoordinate (or the GPS coordinate within a range of coordinates), thematched services are populated on the interface of the watercraft.Aquatic services may also include default services that are populatedregardless of the anchor point identifier. For example, an emergencycall button, a help button and/or the like may populate on the interfaceregardless of the location of the anchor point. In other situations, theaquatic services may be identified by a range of positions. For example,aquatic services may be associated with an upper quarter of an aquaticbody. When the anchor point identifier indicates that the anchor pointis within the upper quarter of an aquatic body, aquatic services for theupper quarter of the aquatic body are populated on the user interface ofthe watercraft.

Interface 400 in FIG. 4 is one example of some aquatic services. As afew examples, aquatic services may include internet services, datatracking, position maintenance services and data, prior aquatic effortdata and services, current aquatic effort data and services, and/orpredictive suggestions data and services. In one aspect, aquaticservices are thinly populated. Aquatic services are thinly populatedwhen data has not been associated with the services. For example,aquatic services are thinly populated when tour data has not beenassociated with an anchor point or there is no prior aquatic dataassociated with the anchor point from prior anglers. In such asituation, the services may include shells when the angler is the firstperson to associate data with anchor point. The interface may provideoptions to the angler to set up and/or customize services for the anchorpoint. In another aspect, the aquatic services ma be richly populated.Aquatic services are richly populated when tours and/or prior aquaticeffort data has been associated with anchor point. In such a situation,an angler may not be prompted to set up the services since they havealready been set up.

Operational flow 700 continuous to operation 708 here current aquaticeffort data is obtained. Current aquatic effort data pane 408 in FIG. 4gives a few examples of current aquatic effort data. To furtherexemplify, current aquatic effort data may include current data fromsensors, current data associated with the control of the watercraft,current data associated with the control of a propelling or trollingdevice, current data associated with a position maintenance routine,time data, date data and/or any other data that may be obtained toidentify a current setting within an aquatic or angling environment. Thecurrent aquatic of effort data may be obtained directly from devicesassociated with the watercraft and/or current aquatic effort data may beobtained from an interne service that queries devices associated withthe watercraft. Current aquatic effort data may also be received from auser input. In other aspects, current aquatic effort data isautomatically obtained. In still other aspects, the current aquaticeffort data is obtained via a network of watercraft and/or a meshnetwork of watercraft.

Operational flow 700 continuous to operation 710 where it is determinedwhether to associate the current aquatic effort data with the aquaticservices. Stated another way, the watercraft automation module mayautomatically associate current aquatic effort data with the aquaticservices in the situation where the angler desires sharing anglinginformation with other anglers or for later access. In other situations,whether the current aquatic effort data is associated with the aquaticservices may be an angler decision that is input upon being prompted. Inother situations, the current aquatic effort data may be locally storedand later uploaded to the aquatic services. In still other situations,the current aquatic effort data may not be associated with the aquaticservices thereby keeping the current aquatic effort data private.

When current aquatic effort data is not associated with aquaticservices, operational flow 700 continues to decision operations 714 asset forth below. When current aquatic effort data is associated withaquatic services, operational flow 700 continues to operation 712 wherethe current aquatic effort data is stored with the aquatic services. Forexample, data from sensors, data from the control of the watercraftand/or trolling device, equipment data, and/or aquatic lire quantity andtype data may be associated with the aquatic services to update theaquatic services. As previously stated, the storage may include a localstorage and/or a remote storage.

Operational flow 700 continues to decision operation 714 where it isdetermined whether other current aquatic effort data is obtained. If so,operational flow 700 loops back to decision operation 710. If not,operational flow 700 continues to decision operation 716 where it isdecided if another anchor point is implicated. Another anchor point maybe implicated, for example, by moving the watercraft to a new GPSlocation or the like. In such a situation, operational flow 700 loopsback to operation 706. If not, operational flow 700 ends at endoperation 718.

FIG. 8 represents one exemplary operational flow diagram for obtainingprior aquatic effort data. Operational flow 800 begins at startoperation 802 and continues to operation 804, where an anchor point isobtained. As stated, an anchor point may include an identifier such as adirectional coordinate, a map coordinate, a GPS identifier and the like.The anchor point may be obtained by a user selection. For example, auser may select a “set anchor” actuator on a display. In such asituation, a GPS coordinate may be received and the anchor point is setto the GPS coordinate. In other situations, an anchor point may beobtained from an internet service, such as a tour service. An anchorpoint may also be a stored anchor point and obtained from a localstorage or a removable storage device. In yet another example, an anchorpoint nut be obtained from another watercraft via a network, theinternet, a radio frequency, infrared frequency or the like. In stillother situations, an anchor point may be associated with a moregeneralized location than the anchor point used to maintain a positionof the watercraft. For example, the anchor point may include thelocation of an aquatic body of interest.

Operational flow 800 continues to operation 806 where aquatic servicesare obtained. Aquatic services may be associated with an internetserver, locally stored on a computing device and/or associated with aremovable computer-readable storage medium. To obtain the services, theidentifier associated with the obtained anchor point is matched toaquatic services. For example, services may be identified b a GPScoordinate. When the GPS identifier of the anchor point matches the GPScoordinate (or the GPS coordinate within a range of coordinates), thematched services are populated on the interface of the watercraft.Aquatic services may also include default services that are populatedregardless of the anchor point identifier. For example, an emergencycall button, a help button and/or the like may populate on the interfaceregardless of the location of the anchor point. In other situations, theaquatic services may be identified by a range of positions. For example,aquatic services may be associated with an upper quarter of an aquaticbody. When the anchor point identifier indicates that anchor point iswithin the upper quarter of an aquatic body, aquatic services arepopulated on the user interface of the watercraft.

Operational flow 800 continues to decision operation 808 where it isdetermined whether prior aquatic effort data is associated with theaquatic services. Prior aquatic effort data pane 406 in FIG. 4 gives afew examples of prior aquatic effort data. To further exemplify, prioraquatic effort data may include prior data from sensors, prior dataassociated with the control of the watercraft, prior data associatedwith the control of a propelling or trolling device, prior dataassociated with a position maintenance routine, prior time data, priordate data and/or any other data that may be have been associated with ananchor point during a prior angling or tour event. The prior aquaticeffort data may be obtained directly from devices associated with thewatercraft and/or prior aquatic effort data may be obtained from aninternet service that queries devices associated with the watercraft. Instill other aspects, the current aquatic effort data is obtained via anetwork of watercraft and/or a mesh network of watercraft.

When prior aquatic effort data is not associated with aquatic services,operational flow 800 continues to decision operations 812 a set forthbelow. When prior aquatic effort data is associated with aquaticservices, operational flow 800 continues to operation 810 where theprior aquatic effort data is displayed on an interface. In the situationwhere the prior aquatic effort data is not locally stared, it may bestored locally. In other aspects, the prior aquatic effort datafacilitates the updating of a position maintenance routine andfacilitates other prediction suggestions as more fully set forth belowin FIG. 9.

Operational flow 800 continues to decision operation 814 where it isdetermined whether another anchor point is obtained. The another anchorpoint may be Obtained as further set forth above. If so, operationalflow 800 loops back to operation 806. If not, operational flow 800continues to end operation 814.

FIG. 9 represents one exemplary operation flow diagram for predictiongeneration. Operational flow 900 begins at start operation 902 andcontinues to operation 904. At operation 904, an anchor point isobtained. An anchor point may include an identifier such as adirectional coordinate, a map coordinate, a GPS identifier and the like.The anchor point may be obtained by a user selection. For example, auser may select a “set anchor” actuator on a display. In such asituation, a GPS coordinate may be received and the anchor point is setat the GPS coordinate. In other situations, an anchor point may beobtained from an internet service, such a is a tour service. An anchorpoint may also be a stored anchor point and obtained from a localstorage or a removable storage device. In yet another example, an anchorpoint may be obtained from another watercraft via a network, theinternet, a ratio frequency, infrared frequency or the like.

Operational flow 900 continues to operation 906 where aquatic servicesare obtained. Aquatic services may be associated with an internetserver, locally stored on a computing device and/or associated with aremovable computer-readable storage medium. To obtains the services, theidentifier associated with the obtained anchor point is matched toaquatic services. For example, services may be identified by a GPScoordinate. When the GPS identifier of the anchor point matches the GPScoordinate (or the GPS coordinate within a of coordinates), the matchedservices are populated on the interface of the watercraft. Aquaticservices may also include default services that are populated regardlessof the anchor point identifier. For example, an emergency call button, ahelp button and/or the like may populate on the interface regardless ofthe location of the anchor point. In other situations the aquaticservices may be identified by a range of positions. For example, aquaticservices may be associated with an upper quarter of an aquatic body.When the anchor point identifier indicates that the anchor point iswithin the upper quarter of an aquatic body, aquatic services arepopulated on the user interface of the watercraft.

Operational flow 900 continues to operation 908 where is determinedwhether current aquatic fort data is obtained. If not, a cannedpredictive suggestion may be generated as more fully set forth below. Ifaquatic effort data is obtained, operational flow 900 to operation 910where the current aquatic effort data is associated with the aquaticservices. Stated another way, the watercraft automation module mayautomatically associate current aquatic effort data with the aquaticservices in the situation where the angler desires sharing anglinginformation with other anglers for later access. In other situations,whether current aquatic effort data is associated with the aquaticservices may be an angler decision that is input upon being prompted. Inother situations, the current aquatic effort data may be locally storedand later uploaded to the aquatic services.

Operational flow 900 continues to decision operation 912 where it isdetermined whether current aquatic effort data matches prior aquaticeffort data. The match may include a perfect match, an absolute match, amatch within a range of values, a match within a preset range, a matchwithin a threshold and the like. The matching criteria may be set by auser, a group of users, an administrator, a software developer, and thelike. A match may include matching a current time, current date and/orcurrent season to a prior time, prior date and/or prior season. A matchmay also include matching a current environmental condition to a priorenvironmental condition. As an example, a current temperature may matcha prior temperature. A match may also include matching a currentwatercraft condition to a prior watercraft condition. As a furtherexample, a match may include matching a current aquatic tour to a prioraquatic tour. As another example, a match may include matching a currentamount of caught aquatic life to a prior amount of caught aquatic life.As another example a match may include matching a current equipment typeto a prior equipment type.

If a match exists, operational flow 900 continues to operation 914 wherea prediction is generated. If a match does not exist, operational flow900 continues to operation 914 where a prediction is generated. Aprediction may be a canned prediction. For example, a prediction mayinclude generalized angling tips, temperature charts, general tips abouta certain area, professional tips, etc. Such canned tips may begenerated when no aquatic effort data is obtained and/or when currentaquatic effort data does not match any prior aquatic effort data.

As an example of a prediction, a current water temperature may be 80degrees and a prior water temperature may be 81 degrees. During theprior aquatic effort where the water was 81 degrees, 25 fish may havebeen caught on a yellow lure. Accordingly, a prediction may be generatedto indicate that a yellow lure should be used. As another example, acurrent wind velocity may be 30 miles per hour and a prior wind velocitymay be 30 miles per hour. During the prior aquatic effort where the windwas 30 miles per hour, 50 fish may have been caught in association withan anchor point in a nearby cove. Accordingly, a prediction may begenerated to automatically control the position maintenance routine topropel the watercraft to the anchor point associated with the cove. Asanother example, a current velocity may be 7 miles an hour. A prior tourmay indicate that it is best to fish a ridge in a river system whiledrifting at 2 miles an hour. Accordingly, a prediction may be generatedto automatically control the drift of the watercraft via the positionmaintenance routine to provide a 2 mile an hour drift from a firstanchor point to a second anchor point. As still another example, acurrent number of caught fish may be 50. Prior aquatic effort dataassociated with a service may indicate that the fishing limit on thelake is 5 fish. Accordingly, a reservation may automatically be made ata restaurant associated with the aquatic services. Other types ofreservations may include hotel reservations actuated on the fishinglimit or on a time of day. The above examples are but a few examples ofa myriad of possible combinations of current aquatic effort conditions,prior aquatic effort conditions, predictions and services. It is evidentfrom the disclosure herein that any number of combinations may exist toproduce one or more predictions and/or to control a watercraft. Also, itshould be evident from the disclosure herein that any number of servicesmay be automated in light of the current aquatic effort conditions andprior aquatic effort conditions.

Operational flow 900 continues to operation 916 where the prediction isoptionally displayed. In the situation where the watercraft automationmodule is configured to automatically control the watercraft in light ofpredictions, the prediction May not be displayed and automaticallycontrol the trolling device. In other situations, the prediction mayinclude a prediction associated with a technique, equipment and thelike. In such a situation, the prediction may be displayed.

Operational flow 900 continues to operation 918 where it is determinedwhether there has been a change in light of current aquatic effort data.If a change is received, operational flow continues to operation 910. Ifa change is not received, operational flow 900 continues to decisionoperation 920. At decision operation 920, it is determined whetheranother anchor point has been obtained. If so, operational flow 900continues to operation 906. If not, operational flow 900 continues toend operation 922.

FIG. 10 represents an exemplary system computing device, such ascomputing device 1000. In a basic configuration, computing device 1000may include any type of stationary computing device or a mobilecomputing device. Computing device 1000 typically includes at least oneprocessing unit 1002 and system memory 1004. Depending on the exactconfiguration and type of computing device, system memory 1004 may bevolatile (such as RAM), non-volatile (such as ROM, flash memory, and thelike) or some combination of the two. System memory 1004 typicallyincludes operating system 1005, one or more applications 1006, and mayinclude program data 100. In one embodiment, applications 1006 furtherinclude application 1020 for a watercraft anchoring and automation. Thisbasic configuration is illustrated in FIG. 10 by those components withindashed line 1008.

Computing device 1000 may also have additional features orfunctionality. For example, computing device 1000 may also includeadditional data storage devices (removable and/or non-removable) suchas, for example, magnetic disks, optical disks, or tape. Such additionalstorage is illustrated in FIG. 10 by removable storage 1009 andnon-removable storage 1010. Computer-readable storage mediums mayinclude volatile and non-volatile, removable and non-removable mediaimplemented in any method or technology for storage of information, suchas computer readable instructions, data structures, program modules orother data. System memory 1004, removable storage 1009 and non-removablestorage 1010 are all examples of computer-readable storage mediums.Computer readable storage mediums includes but are not limited to, RAM,ROM, EEPROM, flash memory or other memory technology, CD-ROM, digitalversatile disks (DVD) or other optical storage, magnetic cassettes,magnetic tape, magnetic disk storage or other magnetic storage devices,or any other medium which can be used to store the desired informationand which can be accessed by computing device 1000. Any suchcomputer-readable storage medium may be part of device 1000. Computingdevice 1000 may also have input device(s) 1012 such as a keyboard,mouse, pen, voice input device, touch input device, etc. Outputdevice(s) 1014 such as a display, speakers, printer, etc. may also beincluded.

Computing device 1000 also contains communication connection(s) 1016that allow the device to communicate with other computing devices 1018,such as over a network or a wireless network. Communicationconnection(s) 1016 is all example of communication media. Communicationmedia typically embodies computer readable instructions, datastructures, program modules or other data in a modulated data signalsuch as a carrier wave or other transport mechanism and includes anyinformation delivery media. The term “modulated data signal” may includea signal that has one or more of its characteristics set or changed insuch a manner as to encode information in the signal. By way of example,and not limitation, communication media may include wired media such asa wired network or direct-wired connection, and Wireless media such asacoustic, RF, infrared and other wireless media.

Although the disclosure has been described in language that is specificto structural features and/or methodological steps, it is to beunderstood that the features defined in the appended claims are notnecessarily limited to the specific features or steps described. Rather,the specific features and steps are disclosed as forms of implementingthe claimed features. Since many embodiments can be made withoutdeparting from the spirit and scope of the disclosure, the inventionresides in the claims hereinafter appended.

What is claimed is:
 1. A trolling device configured to be used on afishing boat, the trolling device comprising: a trolling motor; and acontrol mechanism associated with the trolling motor to control at leastone member of a group consisting of: a speed of the trolling motor and adirection of the trolling motor, wherein the control mechanism includesan interface for establishing a network connection between the controlmechanism and an electronic GPS mapping computer having an electronicdisplay for displaying data, wherein the control mechanism is configuredto receive control instructions from the electronic GPS mapping computerto cause the trolling motor to maintain a controlled drift of thefishing boat with respect to at least one member of a group consistingof: an anchor point, water current rate, water current direction, wind,and wave action.
 2. The trolling device of claim 1, wherein theinterface includes at least one member of a group consisting of: awireless network interface and a wired network interface.
 3. Thetrolling device of claim 1, further comprising a remote for controllingthe control mechanism.
 4. The trolling device of claim 1, wherein theelectronic GPS-equipped mapping computer is a depth finder.
 5. A systemfor controlling a trolling device, the system comprising: a trollingmotor; a control mechanism associated with the trolling motor forcontrolling at least one member of a group consisting of: a speed of thetrolling motor and a direction of the trolling motor; an electronic GPSmapping computer having an electronic display for displaying data; and anetwork connection between the control mechanism and the electronic GPSmapping computer, wherein the electronic GPS mapping computer isconfigured to: receive an indication of a drift factor, wherein thedrift factor includes at least one member of a group consisting of: ananchor point, water current rate, water current direction, wind, andwave action, generate control instructions based on the drift factor,and send instructions to the control mechanism associated with thetrolling motor to cause the control mechanism to control the trollingmotor to maintain a controlled drift of the fishing boat with respect tothe drift factor.
 6. The system of claim 5, wherein the interfaceincludes at least one member of a group consisting of: a wirelessnetwork interface and a wired network interface.
 7. The system of claim5, further comprising a remote for controlling the control mechanism. 8.The system of claim 5, wherein the electronic GPS-equipped mappingcomputer is a depth finder.
 9. A system for controlling a trollingdevice, the system comprising: an electronic GPS mapping computer havingan electronic display for displaying data, wherein the GPS mappingcomputer includes an interface for establishing a network connectionbetween the GPS mapping computer and a control mechanism associated witha trolling motor, and wherein the electronic GPS mapping computer isconfigured to: receive an indication of a drift factor, wherein thedrift factor includes at least one member of a group consisting of: ananchor point, water current rate, water current direction, wind, andwave action, generate control instructions based on the drift factor,and send instructions to the control mechanism associated with thetrolling motor to cause the control mechanism to control the trollingmotor to maintain a controlled drift of the fishing boat with respect tothe drift factor.
 10. The system of claim 9, wherein the interfaceincludes at least one member of a group consisting of: a wirelessnetwork interface and a wired network interface.
 11. The system of claim9, further comprising a remote for controlling the control mechanism.12. The system of claim 9, wherein the electronic GPS-equipped mappingcomputer is a depth finder.